Comparing experiments with modeling for light ion helicon plasma sources

Carter, M. D.; Baity, F. W.; Barber, G. C.; Goulding, R. H.; Mori, Yoshitaka; Sparks, D. O.; White, K. F.; Jaeger, E. F.; Chang‐Diaz, Franklin; Squire, Jared P.

doi:10.1063/1.1519539

Cited by 72 publications

(42 citation statements)

References 24 publications

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“…Though the loading resistance can be computed this way, the equilibrium density cannot be found without considering plasma ionization and transport. Only recently have attempts [30][31][32] been made to couple the helicon equations with transport and continuity equations to give the density profiles. For design purposes, the plasma loading was computed with HELIC for uniform n(r).…”

Section: Computationsmentioning

confidence: 99%

Superiority of half-wavelength helicon antennae

Porte

Yun

Arnush³

et al. 2003

Plasma Sources Sci. Technol.

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Section: Computationsmentioning

confidence: 99%

Superiority of half-wavelength helicon antennae

Porte

Yun

Arnush³

et al. 2003

Plasma Sources Sci. Technol.

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“…15 They have also been used for plasma confinement studies, space-plasma simulation experiments, 16 and are of substantial interest as part of the VASIMR thruster engine for Mars space vehicles. [17][18][19] Recent studies of helicon sources have focused on the physics behind their highly efficient ionization and strong wave damping, which is not fully explained by either collisional or Landau damping processes. The significance of the role of a population of fast electrons constituting a nonMaxwellian component of the electron distribution function in the helicon ionization process is a central question.…”

Section: Introductionmentioning

confidence: 99%

Optical, wave measurements, and modeling of helicon plasmas for a wide range of magnetic fields

et al. 2004

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Helicon waves are excited in a plasma wave facility by a half-turn double-helix antenna operating at 13.56 MHz for static magnetic fields ranging from 200 to 1000 G. A non-perturbing optical probe located outside the Pyrex™ plasma chamber is used to observe 443 nm Ar II emission that is spatially and temporally correlated with the helicon wave. The Ar II emission is measured along with wave magnetic and Langmuir probe density measurements at various axial and radial positions. 105 GHz interferometry is used to verify the bulk temperature corrected Langmuir probe measurements. The measured peak Ar II emission phase velocity is compared to the measured wave magnetic field phase velocity and code predicted wave phase velocity for the transition and blue mode regimes. Very different properties of the optical emission peak phase and wave characteristics for the transition and helicon modes of operation are observed. Comparison of the experimental results with the ANTENAII code ͓Y. Mouzouris and J. E. Scharer, IEEE Trans. Plasma Sci. 24, 152 ͑1996͔͒ is carried out for the wave field measurements for the two regimes of operation.

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“…More recently, the implementation of the iterative solver, using the Multigrid-Incomplete Cholesky Preconditioned Conjugate Gradient Squared method (ICCG) demonstrated good convergence with higher computational speed, compared to the direct solver [6]. The recent upgrade of the EMIR code, EMIR3 [7], includes the calculation of the parallel electric field component, so the system of Eqs. (2) is now solved for all three components.…”

Section: Mathematical Modelmentioning

confidence: 99%